Processing audio signals using a discrete state machine

ABSTRACT

A level of transmit attenuation and a level of receive attenuation are generated using a discrete state machine of a controller. Local audio signals generated with a local microphone are attenuated with a transmit attenuator at the level of transmit attenuation for transmission to a remote node. Remote audio signals received from the remote node are attenuated with a receive attenuator at the level of receive attenuation for playback at a local speaker.

INCORPORATION BY REFERENCE

This application is a continuation-in-part of U.S. patent application Ser. No. 08/342,270, filed Nov. 16, 1994, which is a continuation-in-part of U.S. patent application Ser. No. 08/340,172, filed Nov. 15, 1994, which is a continuation-in-part of U.S. patent application Ser. No. 08/157,694, filed Nov. 24, 1993, now U.S. Pat. No. 5,506,954, all of which are incorporated herein in their entireties by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to audio conferencing, and, in particular, to computer-implemented processes and computer systems for processing audio signals for open audio systems.

2. Description of the Related Art

A traditional telephone handset places the transmitter close to the user's lips and couples the receiver tightly to the user's ear. A speakerphone or other so-called open audio systems replace the handset with a separate microphone and loudspeaker that can be set on a table a few feet from the user. One problem with speakerphones results from acoustic coupling, where the sounds produced by the loudspeaker are picked up by the local microphone and retransmitted back to the sender. The result can be an undesirable echoing in which a talker hears his own voice delayed by the transmission to and retransmission from a remote speakerphone.

One known solution to the problems of acoustic coupling and echoing is voice switching, in which only one direction of transmission is fully active at a time. Systems for achieving this one-way-at-a-time (i.e., half duplex) communication determine which direction is to be active at a given time.

Referring now to FIG. 1, there is shown a circuit block diagram of a conventional speakerphone 10. FIG. 1 is based on FIG. 1 from the seminal article "Fundamental Considerations in the Design of a Voice-Switched Speakerphone" by A. Busala (The Bell System Technical Journal, Vol. XXXIX, No. 2, pp. 265-294, March 1960). As shown in FIG. 1, the voltage levels of local audio signals generated by microphone 12 are attenuated by transmit attenuator 14 for transmission to a remote node. Similar, the voltage levels of remote audio signals received from the remote node are attenuated by receive attenuator 18 for play at loudspeaker 16. The amount of attenuation applied by attenuators 14 and 18 is dynamically controlled by control circuit 19.

To achieve the one-way talk state in which the user of speakerphone 10 talks to the remote participant, control circuit 19 causes receive attenuator 18 to attenuate significantly the remote audio signals received from the remote node, while transmit attenuator 14 permits transmission of the local audio signals to the remote node without significant attenuation. Similarly, to achieve the one-way listen state in which the user of speakerphone 10 listens to the remote participant, control circuit 19 causes transmit attenuator 14 to attenuate significantly the local audio signals, while receive attenuator 18 permits playback of the remote audio signals without significant attenuation.

In conventional systems such as speakerphone 10, the levels of attenuation are determined based on the volumes of the participants, as indicated by the voltage (or energy) levels of the remote and local audio signals. Thus, when one conversation participant starts to speak louder than the other, control circuit 19 controls the attenuation levels of the transmit and receive attenuators 14 and 18 to switch from the talk state to the listen state, or vice versa.

One of the problems with conventional speakerphone systems relates to cutoff, where the system incorrectly or prematurely changes the direction of communication, thereby cutting a talker off before he has completed. It is desirable therefore to provide voice-switched speakerphones that avoid or at least reduce undesirable cutoffs.

It is accordingly an object of the present invention to address the problems associated with undesirable cutoffs when using speakerphones or other open audio systems that rely on voice switching to avoid acoustic coupling.

It is a particular object of the present invention to provide open audio processing for computer-based audio/video conferencing systems.

Further objects and advantages of this invention will become apparent from the detailed description of a preferred embodiment which follows.

SUMMARY OF THE INVENTION

The present invention is an apparatus for processing audio signals. According to a preferred embodiment, the apparatus comprises (a) a transmit attenuator for attenuating local audio signals generated by a local microphone for transmission to a remote node; (b) a receive attenuator for attenuating remote audio signals received from the remote node for playback at a local speaker; and (c) a controller, electrically connected to the transmit attenuator and the receive attenuator, for controlling a level of transmit attenuation for the transmit attenuator and a level of receive attenuation for the receive attenuator. The controller comprises a discrete state machine to generate the level of transmit attenuation and the level of receive attenuation.

The present invention is also a computer-implemented process For processing audio signals. According to a preferred embodiment, a level of transmit attenuation and a level of receive attenuation are generated using a discrete state machine of a controller. Local audio signals generated with a local microphone are attenuated with a transmit attenuator at the level of transmit attenuation for transmission to a remote node. Remote audio signals received from the remote node are attenuated with a receive attenuator at the level of receive attenuation for playback at a local speaker.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, features, and advantages of the present invention will become more fully apparent from the following detailed description of the preferred embodiment, the appended claims, and the accompanying drawings in which:

FIG. 1 is a circuit block diagram of a conventional speakerphone;

FIG. 2 is a block diagram representing real-time point-to-point audio/video conferencing between two computer-based conferencing systems, according to an embodiment of the present invention;

FIG. 3 is a circuit block diagram of the audio systems of the local and remote nodes of the conferencing network of FIG. 2;

FIG. 4 is a process flow diagram of processing implemented by the histogram generators of FIG. 3;

FIG. 5 is a process flow diagram of processing implemented by the state machine of FIG. 3 for each pair of frames of local and remote audio signals to control the attenuation levels of the transmit and receive attenuators of FIG. 3, according to one embodiment of the present invention;

FIG. 6 is a state diagram for the state machine of FIG. 3 for the processing of FIG. 5; and

FIG. 7 is a diagram of a discrete state machine, according to an alternative embodiment of the state machine of FIG. 3.

DESCRIPTION OF THE PREFERRED EMBODIMENT(S)

Referring now to FIG. 2, there is shown a block diagram representing real-time point-to-point audio/video conferencing between two computer-based conferencing nodes, according to one embodiment of the present invention. Each PC node has a conferencing system 100, a camera 102, a microphone 104, a monitor 106, and a speaker 108. The conferencing nodes communicate via a digital network 110. Each conferencing system 100 receives, digitizes, and compresses the analog video signals generated by camera 102 and the analog audio signals generated by microphone 104. The compressed digital video and audio signals are transmitted to the other conferencing node via network 110, where they are decompressed and converted for play on monitor 106 and speaker 108, respectively.

Conferencing system 100 may be any suitable conferencing system and is preferably an Intel® microprocessor-based computer system configured with Intel® ProShare™ conferencing software and hardware. Microphone 104 may be any suitable microphone for generating analog audio signals. Speaker 108 may be any suitable device for playing analog audio signals.

Digital network 110 may be any suitable network for transmitting digital signals between the conferencing nodes. In one embodiment of the present invention, digital network 110 is an ISDN network. In other embodiments, digital network 110 may be other types of networks, such as a local or wide area network.

Referring now to FIG. 3, there is shown a circuit block diagram of the audio systems of the local and remote nodes of the conferencing network of FIG. 2. FIG. 3 represents conferencing in which the local node 302 is configured with an open audio system (e.g., a speakerphone) while the remote node 304 is configured with a closed audio system (e.g., a telephone handset or headset). In an alternative embodiment of the present invention, both local and remote nodes may be configured with open audio systems. The audio processing of FIG. 3 is distributed in that there is an instantiation of the audio processing on each of the conference nodes connected by the digital network 110 and the audio processing on one node is interdependent of the audio processing on the other node.

Local audio signals generated by microphone 306 of local node 302 are attenuated by transmit attenuator 308 for transmission over network 110 to remote node 304, where they are played back at speaker 310. Remote audio signals, generated by microphone 312 of remote node 304 and received by local node 302 over network 110, are attenuated by receive attenuator 314 for playback at speaker 316. State machine 318 controls the level of attenuation (α) applied by transmit attenuator 308 to the local audio stream and the level of attenuation (1-α) applied by receive attenuator 314 to the remote audio stream.

State machine 318 determines these attenuation levels based on the energy levels of the local and remote audio streams (which indicate levels of audio volume) and on histogram information for the local and remote audio streams. In one embodiment of the present invention, the energy levels are based on the mean sum of the squares of the digitized audio signals within a particular time period (i.e., audio frame). The histogram information is used to characterize the energy levels of the background noise of the local and remote audio streams, which in turn are used to determine when the conference participants are talking. The histogram information for the local audio stream is generated by histogram generator 320 of local node 302. The histogram information for the remote audio stream is generated by histogram generator 322 of remote node 304 and received by state machine 318 over network 110.

Referring now to FIG. 4, there is shown a process flow diagram of processing implemented by histogram generator 320 of FIG. 3 for the local audio stream. Histogram generator 320 uses the local audio signals that are generated by microphone 306 over a specified period of time (e.g., 5 seconds) to generate a local histogram (step 402 of FIG. 4). In one embodiment of the present invention, the histogram is logarithm based where each histogram bin corresponds to a specified range of decibels (dB). Histogram generator 320 divides the local audio signals for the previous time period into a plurality of audio frames (e.g., one audio frame=20 msec of audio signals). The histogram is generated by filling the histogram bins based on the energies of the individual audio frames.

After generating the local histogram for the specified time period, histogram generator 320 generates the variance of the local histogram (step 404). The variance is used to determine whether the local audio signals for the previous time period correspond to background noise alone or background noise plus talking. In the paradigm for audio conferencing, background noise is assumed to be relatively uniform, white noise. In this paradigm, when a conference participant is not talking, the histogram variance is relatively small. On the other hand, the histogram variance is relatively large when a conference participant is talking.

Therefore, if the local histogram variance for the previous time period is less than a specified variance threshold (e.g., 3 dB) (step 406), then the local audio signals are assumed to correspond to background noise alone. In this case, the mean of the local histogram is generated (step 408) and used to establish a local background noise threshold (step 410). In one embodiment, the local background noise threshold is 5 dB greater than the local histogram mean. This local background noise threshold is retained and used by state machine 318 to control the transmit and receive attenuators 308 and 314 (as described below).

If, on the other hand, the local histogram variance is not less than the variance threshold (step 406), then the local audio signals for the previous time period are assumed to correspond to background noise plus talking. In this case, the local background noise threshold is not updated and processing returns to step 402. Histogram generator 320 continues to generate and analyze histograms for subsequent time periods to determine whether to update the local background noise threshold.

In the embodiment of FIG. 3, histogram generator 322 of remote node 304 uses processing analogous to that of FIG. 4 to generate a remote histogram for the remote audio signals that are generated by microphone 312 and a remote background noise threshold indicative of the background noise level at remote node 304. In the embodiment of FIG. 3 in which remote node 304 is a closed audio system, the remote background noise threshold is preferably 20 dB greater than the mean of a remote histogram that corresponds to background noise alone. In an alternative embodiment in which both the local and remote nodes are open audio systems, the remote background noise threshold is preferably 5 dB greater than the mean of the remote histogram. The thresholds for open and closed audio systems are selected differently because, in the open audio system, the talker is typically further away from the microphone than in the closed audio system. Histogram generator 322 transmits the remote background noise threshold to state machine 318 over network 110.

In an alternative embodiment of the present invention, the remote node has no histogram generator. In this embodiment, the local node generates its own histogram for the remote audio signals received over the network 110 and does its own histogram analysis analogous to the processing of FIG. 4 to generate the remote background noise threshold for the remote audio signals.

Referring now to FIG. 5, there is shown a process flow diagram of processing implemented by state machine 318 of FIG. 3 for each pair of audio frames (consisting of one frame of local audio signals and one frame of remote audio signals) to control the attenuation levels of transmit and receive attenuators 308 and 314, according to one embodiment of the present invention. In this embodiment, state machine 318 maintains a single continuous state variable i which is used to set the transmit and receive attenuation levels. The state variable i can assume any value between -j and j, where j is a specified constant (e.g., 8).

Referring now to FIG. 6, there is shown a state diagram for state machine 318 of FIG. 3 for the processing of FIG. 5. When the state variable i is between -j and -k, where k is a specified constant less than j (e.g., 2), state machine 318 is in the listen state 602 and the attenuators are configured to permit the local user to listen to the remote user talk. When the state variable i is between k and j, state machine 318 is in the talk state 606 and the attenuators are configured to permit the local user to talk to the remote user. When the state variable i is between -k and k, state machine 318 is in the idle state 604. The idle state is a transition state between the listen and talk states in which the attenuators are configured to allow both local and remote users to talk.

State machine 318 analyzes the energy levels of the attenuated local audio signals T and the remote audio signals R (as shown in FIG. 3) for the most recent local and remote audio frames to determine the current mode of audio conferencing. There are five different audio conferencing modes, defined as follows:

No Talking: (T≦τ_(L)) & (R≦τ_(R))

Single Talk (Local): (T>τ_(L)) & (R≦τ_(R))

Single Talk (Remote): (T≦τ_(L)) & (R>τ_(R))

Double Talk (Local Wins): (T>τ_(L)) & (R>τ_(R)) & (T>R+D1)

Double Talk (Remote Wins): (T>τ_(L)) & (R>τ_(R)) & (R>T+D2)

where τ_(L) is the local background noise threshold, τ_(R) is the remote background noise threshold, and D1 and D2 are threshold parameters (e.g., 10 dB for both D1 and D2).

Referring again to FIG. 5, if the current audio conferencing mode is the no talking mode (step 502), then state machine 318 slowly moves the state variable i towards the idle state (step 504). To move slowly towards the idle state, if the state variable i is greater than 0, then state machine 318 decrements the state variable i by 1, and, if the state variable i is less than 0, then state machine 318 increments the state variable i by 1. If the state variable i is equal to zero, then it is left unchanged.

If the current audio conferencing mode is the single talk (local) mode (step 506), then state machine 318 quickly moves the state variable i towards the talk state (step 508). To move quickly towards the talk state, state machine 318 increments the state variable i by l, where l is a specified constant greater than k (e.g., l=10) and where the state variable i cannot be greater than j.

If the current audio conferencing mode is the single talk (remote) mode (step 510), then state machine 318 quickly moves the state variable i towards the listen state (step 512). To move quickly towards the listen state, state machine 318 decrements the state variable i by l, where the state variable i cannot be less than -j.

If the current audio conferencing mode is the double talk (local wins) mode (step 514), then state machine 318 quickly moves the state variable i towards the talk state (step 516). If the current audio conferencing mode is the double talk (remote wins) mode (step 518), then state machine 318 quickly moves the state variable i towards the listen state (step 520). Otherwise, state machine 318 leaves the state variable i unchanged (step 522).

After determining the current audio conferencing mode and adjusting the state variable i accordingly, state machine 318 sets the transmit and receive attenuation levels based on the state variable i (step 524). In one embodiment of the present invention, the sum of the transmit and receive attenuation levels always correspond to unity gain. In this embodiment, the attenuation level for transmit attenuator 308 of FIG. 3 may be represented by α and the attenuation level for receive attenuator 314 may be represented by (1-α).

As shown in FIG. 6, when the state variable i is less than -k, then state machine 318 is in the listen state 602 and state machine 318 sets α equal to 0. As such, the attenuation level of transmit attenuator 308 is 0 and the attenuation level of receive attenuator 314 is 1. In this configuration, the local audio signals generated by microphone 306 are fully attenuated and the remote audio signals are unattenuated to permit them to be played back at speaker 316, thereby achieving one-way (i.e., half duplex) communication.

When the state variable i is greater than k, then state machine 318 is in the talk state 606 and state machine 318 sets α equal to 1. As such, the attenuation level of transmit attenuator 308 is 1 and the attenuation level of receive attenuator 314 is 0. In this configuration, the local audio signals are unattenuated and the remote audio signals are fully attenuated to prevent them from being played back at speaker 316, thereby achieving one-way communication.

When the state variable i is between -k and k, then state machine 318 is in the idle state 604 and state machine 318 sets α as shown in the following Equation (1):

    α=(i+k)/2k.                                          (1)

In this configuration, both the local and remote audio signals are partially attenuated. The idle state provides a continuous linear transition for α between the listen and talk states, where α varies from 0 (for i=-k) to 1 (for i=k).

Referring now to FIG. 7, there is shown a diagram of a discrete state machine 700, according to an alternative embodiment of state machine 318 of FIG. 3. Discrete state machine 700 comprises the following five states defined by the present five sets of conditions:

(1) No Talking state 702: (T≦τ_(L)) & (R≦τ_(R))

(2) Single Talk (Local) state 704: (T>τ_(L)) & (R≦τ_(R))

(3) Single Talk (Remote) state 706: (T≦τ_(L)) & (R>τ_(R))

(4) Double Talk (Local Wins) state 708: (T>τ_(L)) & (R>τ_(R)) & [(T-τ_(L) )-(R-τ_(R))]>D1)

(5) Double Talk (Remote Wins) state 710: (T>τ_(L)) & (R>τ_(R)) & [(R-τ_(R))-(L-τ_(L))]>D2)

where T is the energy of the current frame of attenuated local audio signals, R is the energy of the current frame of remote audio signals, τ_(L) is the local background noise threshold, τ_(R) is the remote background noise threshold, and D1 and D2 are threshold parameters (e.g., 10 dB for both D1 and D2).

As shown in FIG. 7, the possible transitions between states in discrete state machine 700 are limited to the following:

From No Talking state 702 to either Single Talk (Local) state 704 or Single Talk (Remote) state 706;

From Single Talk (Local) state 704 to either No Talking state 702, Double Talk (Local Wins) state 708, or Double Talk (Remote Wins) state 710;

From Single Talk (Remote) state 706 to either No Talking state 702, Double Talk (Local Wins) state 708, or Double Talk (Remote Wins) state 710;

From Double Talk (Local Wins) state 708 to only Single Talk (Local) state 704; and

From Double Talk (Remote Wins) state 710 to only Single Talk (Remote) state 706.

Thus, for example, if the state for the previous cycle was the No Talking state 702, then, during the current cycle, the processing for discrete state machine 700 needs only determine whether the conditions for either the Single Talk (Local) state 704 or the Single Talk (Remote) state 706 are met. If one of those two sets of conditions are met, then the corresponding state transition will occur. Those skilled in the art will understand that this discrete state machine processing differs from the linear state machine processing of FIG. 5 in which the conditions for all five modes may need to be checked in a given cycle.

In one embodiment of the present invention, the transmit and receive attenuation levels For an audio system using discrete state machine 700 of FIG. 7 are determined in the same manner as the transmit and receive attenuation levels that were described earlier for the audio system using the state machine processing of FIG. 5. That is, the transmit attenuation level α and the receive attenuation level (1-α) are based on the state variable i and constant k, where:

for i<-k, α=0

for -k≦i≦k, α=(i+k)/2k

for k<i, α=1

and where i is limited to the range (-j,j). In one embodiment, (j=8) and (k=2).

When a state transition occurs (and only when a state transition occurs), the state variable i is incremented (or decremented). The change to the state variable i for each of the allowable state transitions is indicated in FIG. 7 as either a slow step or a fast step. In one embodiment of the present invention, the slow step has a magnitude of 1 and the fast step has a magnitude of l, where l is greater than k (e.g., l=10).

Those skilled in the art will understand that, in addition to the audio processing described above, local node 302 of FIG. 3 may also compress the local audio signals for transmission to the remote node and decompress compressed remote audio signals for playback.

It will also be understood that alternative embodiments of the present invention may be based on the pre-attenuated local audio signals M of FIG. 3 rather than on the attenuated local audio signals T.

In one embodiment of the present invention, the network 110 of FIG. 3 is an ISDN network. In this embodiment, the local and remote audio signals are transmitted between the nodes over the B channels of the ISDN network. To avoid redundant operations between the two nodes and to avoid audio codec distortions to the energy levels, the audio frame energy (T or R) is embedded within a field of the communication format that carries the digitally compressed audio signals for each frame. The following information is transmitted infrequently over the B channels of the ISDN network:

The local background noise threshold τ_(L) sent from the local node to the remote node; and

The remote background noise threshold τ_(R) sent from the remote node to the local node.

The infrequent communications are transmitted less frequently than the frame communications (e.g., typically every 5 seconds rather than every 20 milliseconds).

In the embodiment shown in FIG. 3, the local node is an open audio system while the remote node is a closed audio system. In another embodiment of the present invention, both nodes are open audio systems, in which case the remote node performs processing analogous to that described above for the local node. In this latter embodiment, the local background noise threshold τ_(L) is transmitted from the local node to the remote node in addition to the remote background noise threshold τ_(R) being transmitted from the remote node to the local node.

In yet another embodiment of the present invention, the remote node does not have a histogram generator. In this embodiment, the local node performs the histogram analysis of the remote audio stream received from the remote node to generate and update the remote background noise threshold.

Those skilled in the art will understand that the audio systems of the present invention permit two personal computer (PC) based nodes connected by a digital network to carry on an audio conversation utilizing microphones and speakers without having to resort to other measures which limit or eliminate acoustic feedback or coupling from speaker to microphone. As such, there is no need for an audio headset or similar device to eliminate acoustic coupling. Nor is a commercial speakerphone attachment (i.e., a separate dedicated circuit device) needed which would perform the audio processing off the PC and would add cost and complexity to the system.

The present invention works with any configuration of one or more microphones and one or more speakers and not just with a commercial speakerphone in which the microphone and speaker are fixed within an enclosure.

It will also be understood that, by transmitting threshold and energy level information between the nodes, the present invention effectively distributes computational overhead among the nodes such that redundant signal processing (e.g., generation of signal volumes and background noise thresholds) is eliminated. This also helps make the nodes immune to any losses or distortions that may result from the compression and decompression processing.

It will be further understood that various changes in the details, materials, and arrangements of the parts which have been described and illustrated in order to explain the nature of this invention may be made by those skilled in the art without departing from the principle and scope of the invention as expressed in the following claims. 

What is claimed is:
 1. An apparatus for processing audio signals, comprising:(a) a transmit attenuator for attenuating local audio signals generated by a local microphone for transmission to a remote node; (b) a receive attenuator for attenuating remote audio signals received from the remote node for playback at a local speaker; and (c) a controller, electrically connected to the transmit attenuator and the receive attenuator, for controlling a level of transmit attenuation for the transmit attenuator and a level of receive attenuation for the receive attenuator, wherein the controller comprises a discrete state machine to generate the level of transmit attenuation and the level of receive attenuation, wherein the discrete state machine comprises a no talking state, a single talk (local) state, a single talk (remote) state, and at least one double talk state.
 2. The apparatus of claim 1, wherein the controller controls the sum of the level of transmit attenuation and the level of receive attenuation to correspond to unity gain.
 3. The apparatus of claim 1, wherein the controller generates the levels of transmit and receive attenuation based on:an energy level for the local audio signals; an energy level for local background noise; an energy level for the remote audio signals; and an energy level for remote background noise.
 4. The apparatus of claim 1, wherein:the discrete state machine generates a continuous state variable i; and the discrete state machine uses the continuous state variable i to generate the level of transmit attenuation and the level of receive attenuation.
 5. The apparatus of claim 4, wherein the discrete state machine changes the continuous state variable i at two or more different rates, where the different rates correspond to different configurations of the local and remote audio signals.
 6. The apparatus of claim 1, wherein the discrete state machine comprises the no talking state, the single talk (local) state, the single talk (remote) state, a double talk (local wins) state, and a double talk (remote wins) state.
 7. The apparatus of claim 6, wherein:if (T≦τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the no talking state; if (T>τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the single talk (local) state; if (T≦τ_(L)) & (R>τ_(R)), then the discrete state machine is in the single talk (remote) state; if (T>τ_(L)) & (R>τ_(R)) & [(T-τ_(L))-(R-τ_(R))]>D1), then the discrete state machine is in the double talk (local wins) state; and if (T>τ_(L)) & (R>τ_(R)) & [(R-τ_(R))-(L-τ_(L))]>D2), then the discrete state machine is in the double talk (remote wins) state, wherein:T is an energy for the local audio signals; R is an energy for the remote audio signals; τ_(L) is a local background noise threshold; τ_(R) is a remote background noise threshold; and D1 and D2 are specified threshold parameters.
 8. The apparatus of claim 7, wherein state transitions for the discrete state machine comprise:from the no talking state to either the single talk (local) state or the single talk (remote) state; from the single talk (local) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the single talk (remote) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the double talk (local wins) state to only the single talk (local) state; and from the double talk (remote wins) state to only the single talk (remote) state.
 9. The apparatus of claim 8, wherein:when the state transition is from the no talking state to the single talk (local) state, the discrete state machine increments a continuous state variable i by a fast step; when the state transition is from the no talking state to the single talk (remote) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the single talk (local) state to the no talking state, the discrete state machine decrements the continuous state variable i by a slow step; when the state transition is from the single talk (local) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; when the state transition is from the single talk (local) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the single talk (remote) state to the no talking state, the discrete state machine increments the continuous state variable i by the slow step; when the state transition is from the single talk (remote) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; when the state transition is from the single talk (remote) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the double talk (local wins) state to the single talk (local) state, the discrete state machine decrements the continuous state variable i by the slow step; and when the state transition is from the double talk (remote wins) state to the single talk (remote) state, the discrete state machine increments the continuous state variable i by the slow step.
 10. The apparatus of claim 9, wherein:when the continuous state variable i is between -j and -k, the controller sets the level of transmit attenuation to 0 and the level of receive attenuation to 1, wherein:-j≦i≦j; j is a specified positive constant; and k is a specified positive constant less than j; when the continuous state variable i is between k and j, the controller sets the level of transmit attenuation to 1 and the level of receive attenuation to 0; and when the continuous state variable i is between -k and k, the controller sets the level of transmit attenuation to α and the level of receive attenuation to (1-α), wherein 0≦α≦1.
 11. The apparatus of claim 10, wherein, when the continuous state variable i is between -k and k,α=(i+k)/2k.
 12. The apparatus of claim 1, wherein:the discrete state machine comprises the no talking state, the single talk (local) state, the single talk (remote) state, a double talk (local wins) state, and a double talk (remote wins) state; if (T≦τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the no talking state; if (T>τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the single talk (local) state; if (T≦τ_(L)) & (R>τ_(R)), then the discrete state machine is in the single talk (remote) state; if (T>τ_(L)) & (R>τ_(R)) & [(T-τ_(L))-(R-τ_(R))]>D1), then the discrete state machine is in the double talk (local wins) state; if (T>τ_(L)) & (R>τ_(R)) & [(R-τ_(R))-(L-τ_(L))]>D2), then the discrete state machine is in the double talk (remote wins) state, wherein:T is an energy for the local audio signals; R is an energy for the remote audio signals; τ_(L) is a local background noise threshold; τ_(R) is a remote background noise threshold; and D1 and D2 are specified threshold parameters; state transitions for the discrete state machine comprise:from the no talking state to either the single talk (local) state or the single talk (remote) state; from the single talk (local) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the single talk (remote) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the double talk (local wins) state to only the single talk (local) state; and from the double talk (remote wins) state to only the single talk (remote) state; when the state transition is from the no talking state to the single talk (local) state, the discrete state machine increments a continuous state variable i by a fast step; when the state transition is from the no talking state to the single talk (remote) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the single talk (local) state to the no talking state, the discrete state machine decrements the continuous state variable i by a slow step; when the state transition is from the single talk (local) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; when the state transition is from the single talk (local) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the single talk (remote) state to the no talking state, the discrete state machine increments the continuous state variable i by the slow step; when the state transition is from the single talk (remote) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; when the state transition is from the single talk (remote) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; when the state transition is from the double talk (local wins) state to the single talk (local) state, the discrete state machine decrements the continuous state variable i by the slow step; when the state transition is from the double talk (remote wins) state to the single talk (remote) state, the discrete state machine increments the continuous state variable i by the slow step; when the continuous state variable i is between -j and -k, the controller sets the level of transmit attenuation to 0 and the level of receive attenuation to 1, wherein:-j≦i≦j; j is a specified positive constant; and k is a specified positive constant less than j; when the continuous state variable i is between k and j, the controller sets the level of transmit attenuation to 1 and the level of receive attenuation to 0; and when the continuous state variable i is between -k and k, the controller sets the level of transmit attenuation to α and the level of receive attenuation to (1-α), wherein α=(i+k)/2k.
 13. A computer-implemented process for processing audio signals, comprising the steps of:(a) generating a level of transmit attenuation and a level of receive attenuation using a discrete state machine of a controller, wherein the discrete state machine comprises a no talking state, a single talk (local) state, a single talk (remote) state, and at least one double talk state; (b) attenuating, with a transmit attenuator at the level of transmit attenuation, local audio signals generated with a local microphone for transmission to a remote node; and (c) attenuating, with a receive attenuator at the level of receive attenuation, remote audio signals received from the remote node for playback at a local speaker.
 14. The process of claim 13, wherein step (a) comprises the step of controlling the sum of the level of transmit attenuation and the level of receive attenuation to correspond to unity gain.
 15. The process of claim 13, wherein step (a) comprises the step of generating the levels of transmit and receive attenuation based on:an energy level for the local audio signals; an energy level for local background noise; an energy level for the remote audio signals; and an energy level for remote background noise.
 16. The process of claim 13, wherein step (a) comprises the steps of:(1) generating a continuous state variable i with the discrete state machine; and (2) using the continuous state variable i by the discrete state machine to generate the level of transmit attenuation and the level of receive attenuation.
 17. The process of claim 16, wherein step (a)(1) comprises the step of changing the continuous state variable i at two or more different rates, where the different rates correspond to different configurations of the local and remote audio signals.
 18. The process of claim 13, wherein the discrete state machine comprises the no talking state, the single talk (local) state, the single talk (remote) state, a double talk (local wins) state, and a double talk (remote wins) state.
 19. The process of claim 18, wherein:if (T≦τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the no talking state; if (T>τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the single talk (local) state; if (T≦τ_(L)) & (R>τ_(R)), then the discrete state machine is in the single talk (remote) state; if (T>τ_(L)) & (R>τ_(R)) & [(T-τ_(L))-(R-τ_(R))]>D1), then the discrete state machine is in the double talk (local wins) state; and if (T>τ_(L)) & (R>τ_(R)) & [(R-τ_(R))-(L-τ_(L))]>D2), then the discrete state machine is in the double talk (remote wins) state, wherein:T is an energy for the local audio signals; R is an energy for the remote audio signals; τ_(L) is a local background noise threshold; τ_(R) is a remote background noise threshold; and D1 and D2 are specified threshold parameters.
 20. The process of claim 19, wherein step (a) comprises the step of implementing state transitions by the discrete state machine, wherein the state transitions comprise:from the no talking state to either the single talk (local) state or the single talk (remote) state; from the single talk (local) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the single talk (remote) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the double talk (local wins) state to only the single talk (local) state; and from the double talk (remote wins) state to only the single talk (remote) state.
 21. The process of claim 20, wherein step (a) comprises the steps of:(1) when the state transition is from the no talking state to the single talk (local) state, the discrete state machine increments a continuous state variable i by a fast step; (2) when the state transition is from the no talking state to the single talk (remote) state, the discrete state machine decrements the continuous state variable i by the fast step; (3) when the state transition is from the single talk (local) state to the no talking state, the discrete state machine decrements the continuous state variable i by a slow step; (4) when the state transition is from the single talk (local) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; (5) when the state transition is from the single talk (local) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; (6) when the state transition is from the single talk (remote) state to the no talking state, the discrete state machine increments the continuous state variable i by the slow step; (7) when the state transition is from the single talk (remote) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; (8) when the state transition is from the single talk (remote) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; (9) when the state transition is from the double talk (local wins) state to the single talk (local) state, the discrete state machine decrements the continuous state variable i by the slow step; and (10) when the state transition is from the double talk (remote wins) state to the single talk (remote) state, the discrete state machine increments the continuous state variable i by the slow step.
 22. The process of claim 21, wherein: step (a) further comprises the steps of:(11) when the continuous state variable i is between -j and -k, the controller sets the level of transmit attenuation to 0 and the level of receive attenuation to 1, wherein:-j≦i≦j; j is a specified positive constant; and k is a specified positive constant less than j; (12) when the continuous state variable i is between k and j, the controller sets the level of transmit attenuation to 1 and the level of receive attenuation to 0; and (13) when the continuous state variable i is between -k and k, the controller sets the level of transmit attenuation to α and the level of receive attenuation to (1-α), wherein 0≦α≦1.
 23. The process of claim 22, wherein, when the continuous state variable i is between -k and k,α=(i+k)2k.
 24. The process of claim 1, wherein:the discrete state machine comprises the no talking state, the single talk (local) state, the single talk (remote) state, a double talk (local wins) state, and a double talk (remote wins) state; if (T≦α_(L)) & (R≦τ_(R)), then the discrete state machine is in the no talking state; if (T>τ_(L)) & (R≦τ_(R)), then the discrete state machine is in the single talk (local) state; if (T≦τ_(L)) & (R>τ_(R)), then the discrete state machine is in the single talk (remote) state; if (T>τ_(L)) & (R>τ_(R)) & [(T-τ_(L))-(R-τ_(R))]>D1), then the discrete state machine is in the double talk (local wins) state; if (T>τ_(L)) & (R>τ_(R)) & [(R-τ_(R))-(L-τ_(L))]>D2), then the discrete state machine is in the double talk (remote wins) state, wherein:T is an energy for the local audio signals; R is an energy for the remote audio signals; τ_(L) is a local background noise threshold; τ_(R) is a remote background noise threshold; and D1 and D2 are specified threshold parameters:step (a) comprises the steps of: (1) implementing state transitions by the discrete state machine, wherein the state transitions comprise:from the no talking state to either the single talk (local) state or the single talk (remote) state; from the single talk (local) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the single talk (remote) state to either the no talking state, the double talk (local wins) state, or the double talk (remote wins) state; from the double talk (local wins) state to only the single talk (local) state; and from the double talk (remote wins) state to only the single talk (remote) state; (2) when the state transition is from the no talking state to the single talk (local) state, the discrete state machine increments a continuous state variable i by a fast step; (3) when the state transition is from the no talking state to the single talk (remote) state, the discrete state machine decrements the continuous state variable i by the fast step; (4) when the state transition is from the single talk (local) state to the no talking state, the discrete state machine decrements the continuous state variable i by a slow step; (5) when the state transition is from the single talk (local) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; (6) when the state transition is from the single talk (local) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; (7) when the state transition is from the single talk (remote) state to the no talking state, the discrete state machine increments the continuous state variable i by the slow step; (8) when the state transition is from the single talk (remote) state to the double talk (local wins) state, the discrete state machine increments the continuous state variable i by the fast step; (9) when the state transition is from the single talk (remote) state to the double talk (remote wins) state, the discrete state machine decrements the continuous state variable i by the fast step; (10) when the state transition is from the double talk (local wins) state to the single talk (local) state, the discrete state machine decrements the continuous state variable i by the slow step; (11) when the state transition is from the double talk (remote wins) state to the single talk (remote) state, the discrete state machine increments the continuous state variable i by the slow step; (12) when the continuous state variable i is between -j and -k, the controller sets the level of transmit attenuation to 0 and the level of receive attenuation to 1, wherein:-j≦i≦j; j is a specified positive constant; and k is a specified positive constant less than j; (13) when the continuous state variable i is between k and j, the controller sets the level of transmit attenuation to 1 and the level of receive attenuation to 0; and (14) when the continuous state variable i is between -k and k, the controller sets the level of transmit attenuation to a and the level of receive attenuation to (1-α), wherein α=(i+k)/2k. 